The stimulatory guanine-nucleotide regulatory unit of adenylate cyclase from bovine cerebral cortex. ADP-ribosylation and purification

The neuropeptide Y (NPY) Y2 receptors are largely dimeric in the kidney, but monomeric in the forebrain

The neuropeptide Y(NPY) Y2 receptors are detected largely as dimers in the clonal expressions in CHO cells and in particulates from rabbit kidney cortex. However, in two areas of the forebrain (rat or rabbit piriform cortex and hypothalamus), these receptors are found mainly as monomers. Evidence is presented that this difference relates to large levels of G proteins containing the Gi alpha -subunit in the forebrain areas. The predominant monomeric status of these Y2 receptors should also be physiologically linked to large synaptic inputs of the agonist NPY. The rabbit kidney and the human CHO cell-expressed Y2 dimers are converted by agonists to monomers in vitro at a similar rate in the presence of divalent cations.

Effect of deletion of the major brain G-protein alpha subunit (alpha(o)) on coordination of G-protein subunits and on adenylyl cyclase activity

Heterotrimeric G-proteins, composed of alpha and betagamma subunits, transmit signals from cell-surface receptors to cellular effectors and ion channels. Cellular responses to receptor agonists depend on not only the type and amount of G-protein subunits expressed but also the ratio of alpha and betagamma subunits. Thus far, little is known about how the amounts of alpha and betagamma subunits are coordinated. Targeted disruption of the alpha(o) gene leads to loss of both isoforms of alpha(o), the most abundant alpha subunit in the brain. We demonstrate that loss of alpha(o) protein in the brain is accompanied by a reduction of beta protein to 32+/-2% (n = 4) of wild type. Sucrose density gradient experiments show that all of the betagamma remaining in the brains of alpha(o)-/- mice sediments as a heterotrimer (s20,w = 4.4 S, n = 2), with no detectable free alpha or betagamma subunits. Thus, the level of the remaining betagamma subunits matches that of the remaining alpha subunits. Protein levels of alpha subunits other than alpha(o) are unchanged, suggesting that they are controlled independently. Coordination of betagamma to alpha occurs posttranscriptionally because the mRNA level of the predominant beta1 subtype in the brains of alpha(o)-/- mice was unchanged. Adenylyl cyclase can be positively or negatively regulated by betagamma. Because the level of other alpha subunits is unchanged and alpha(o) itself has little or no effect on adenylyl cyclase, we could examine how a large change in the level of betagamma affects this enzyme. Surprisingly, we could not detect any difference in the adenylyl cyclase activity between brain membranes from wild-type and alpha(o)-/- mice. We propose that alpha(o) and its associated betagamma are sequestered in a distinct pool of membranes that does not contribute to the regulation of adenylyl cyclase.

Maintenance of cellular levels of G-proteins: different efficiencies of alpha s and alpha o synthesis in GH3 cells

G-proteins couple membrane-bound receptors to intracellular effectors. Each cell has a characteristic complement of G-protein alpha, beta and gamma subunits that partly determines the cell's response to external signals. Very little is known about the mechanisms that set and maintain cellular levels of G-proteins or about potential points of regulation. We have assayed the steady-state levels of mRNA and protein for two types of G-protein subunits, alpha s and alpha o, in rat brain, heart and GH3 cells, and found that in all these cases, it takes 9- to 20-fold more mRNA to produce a given amount of alpha s protein than to produce the same amount of alpha o protein. Such a situation could arise from a relatively rapid rate of alpha s protein degradation, requiring rapid protein synthesis to compensate, or from relatively inefficient translation of alpha s mRNA compared with alpha o mRNA. The latter appears to be the case in GH3 cells. These cells contain 94 times more mRNA for alpha s than for alpha o, yet the rate of alpha s protein synthesis is only 9 times greater than alpha o protein synthesis. The degradation rates of the two proteins are similar (13 h for alpha s and 18 h for alpha o). To begin to define the mechanism that accounts for the fact that it takes more mRNA to synthesize a given amount of alpha s than alpha o, we asked whether there is a pool of alpha s mRNA that does not participate in protein synthesis. We found that virtually all alpha s and alpha o mRNA is associated with ribosomes. Therefore, all the mRNA is likely to be capable of directing protein synthesis. Since the rate-limiting step in protein synthesis is usually binding of the ribosome to mRNA at initiation, our results suggest that the relatively slow rate of alpha s protein synthesis is regulated by a mechanism that acts beyond initiation at peptide elongation and/or termination.

The G protein beta subunit Gpb1 of Schizosaccharomyces pombe is a negative regulator of sexual development

A Schizosaccharomyces pombe homolog of mammalian genes encoding G protein beta subunits, gpb1+, was cloned by the polymerase chain reaction using primer pairs that correspond to sequences conserved in several G beta genes of other species followed by screening of genomic and cDNA libraries. The gpb1 gene encodes 317 amino acids that show 47% homology with human G beta 1 and G beta 2 and 40% homology with Saccharomyces cerevisiae G beta protein. Disruption of the gpb1 gene indicated that this gene is not required for vegetative cell growth. However, gpb1-disrupted haploid cells mated and sporulated faster than wild-type cells, both in sporulation (MEA) and in complex medium (YE): when examined 23 h after transfer to sporulation medium, 35% of gpb1-disrupted haploid pairs had undergone conjugation and sporulation, whereas only 3-5% of wild-type haploid pairs had done so. Overexpression of the gpb1 gene suppressed this facilitated conjugation and sporulation phenotype of gpb1-disrupted cells but did not cause any obvious effect in wild-type cells. Co-disruption of one of the two S. pombe G alpha-subunit genes, gpa2, in the gpb1-disrupted cells did not change the accelerated conjugation and sporulation phenotype of the gpb1- cells. However, co-disruption of the ras1 gene abolished the gpb1- phenotype. These results suggest that Gpb1 is a negative regulator of conjugation and sporulation that apparently works upstream of Ras1 function in S. pombe. The possible relationship of Gpb1 to two previously identified, putative G alpha proteins of S. pombe is discussed.

GTP-binding proteins are restricted to signal transduction sites

We have used the Torpedo electric organ to study GTP-binding protein localization since functionally distinct membrane fractions can be isolated from this tissue. Postsynaptic membranes from the innervated face and membranes from the non-innervated face of the electrocyte, as well as presynaptic membranes from the innervating nerve, can be isolated. alpha s was restricted to the innervated face of the postsynaptic cell; alpha i, alpha o, and ras were found only in the presynaptic membrane fraction of the innervating nerve. 21 and 25 kDa GTP-binding proteins were present in all the membrane fractions. These results suggest that specific GTP-binding proteins are differentially restricted to membrane areas specialized in signal transduction.

Characterization of functional GTP binding proteins in Jurkat T cell mutants lacking either CD3-Ti or CD2 surface receptors

G proteins are membrane-bound molecules involved in coupling of surface receptors with signal transduction effector systems in multiple cell types including T lymphocytes. Given that mature T cells which lack antigen receptors (CDl-Ti) are refractory to stimulation through CD2 or other accessory molecules, T cell receptor components likely play a critical role in coupling surface receptors with signal transduction effectors. It has recently been proposed that modulation of T cell receptor components with MAbs results in a physical loss or functional inactivation of G protein(s). In view of the importance of the T cell activation process, we herein examined G proteins in untreated or antibody-modulated Jurkat T cells as well as in genetic variants lacking either CD3-Ti or CD2 surface receptors. 43- and 41-kDa G protein alpha chains are ADP ribosylated with cholera (CTX) and pertussis (PTX) toxins, respectively, in wild type and receptor minus cell populations. In the wild type Jurkat cell line as well as in CD3- and CD2- variants, AlF4- can activate the G protein(s) presumably associated with phospholipase C to generate polyphosphoinositide turnover as well as an increase in cytoplasmic free calcium ions. Furthermore, G protein(s) linked to adenylylcyclase, a pathway which inhibits T lymphocyte activation, can be directly activated with CTX in the absence of CD3-Ti or CD2 on the membrane. Importantly, AlF4- can also induce polyphosphoinositide turnover in Jurkat cells whose T cell receptor proteins have been modulated with anti-CD3 MAb. These data provide functional and biochemical evidence that at least certain G proteins are intact in the absence of surface expression of CD3-Ti or CD2 molecules and imply that CD3-Ti desensitization is not singularly due to G protein loss.

Quantification of the alpha and beta subunits of the transducing elements (Gs and Gi) of adenylate cyclase in adipocyte membranes from lean and obese (ob/ob) mice

The abundance of the alpha and beta subunits of the GTP-binding proteins (G-proteins) that transduce hormonal messages to adenylate cyclase was assessed in adipocyte membranes from lean (+/+) and obese (ob/ob) mice, using ADP-ribosylation with bacterial toxin and immunodetection. Both methods revealed two Gs alpha species (48 and 42 kDa) in the membranes. Compared with those of lean mice, the membranes from obese mice contained substantially less of the 48 kDa species of Gs alpha, as assessed by both methods. ADP-ribosylation by pertussis toxin showed that only half as much ADP-ribose was incorporated into Gi alpha in the membranes from obese as compared with lean mice. Immunodetection revealed two separate Gi alpha peptides (39 and 40 kDa) and showed that the 40 kDa species was less abundant in the membranes from obese mice, whereas the amount of the 39 kDa species was similar in membranes from both lean and obese animals. Based on ADP-ribosylation assays, in membranes from lean mice the ratio Gs alpha/Gi alpha was 1:16, whereas in the membranes from obese mice it was 1:10. Similar amounts of immunodetectable beta peptide were found in both types of membranes. On the basis of the currently accepted dissociation model of adenylate cyclase activation, the decrease in the abundance of the Gi alpha subunit in adipocyte membranes from obese mice could account for the abnormal kinetics of the enzyme in these membranes.

Stoichiometry of G protein subunits affects the Saccharomyces cerevisiae mating pheromone signal transduction pathway

The Saccharomyces cerevisiae GPA1, STE4, and STE18 genes encode products homologous to mammalian G-protein alpha, beta, and gamma subunits, respectively. All three genes function in the transduction of the signal generated by mating pheromone in haploid cells. To characterize more completely the role of these genes in mating, we have conditionally overexpressed GPA1, STE4, and STE18, using the galactose-inducible GAL1 promoter. Overexpression of STE4 alone, or STE4 together with STE18, generated a response in haploid cells suggestive of pheromone signal transduction: arrest in G1 of the cell cycle, formation of cellular projections, and induction of the pheromone-inducible transcript FUS1 25- to 70-fold. High-level STE18 expression alone had none of these effects, nor did overexpression of STE4 in a MATa/alpha diploid. However, STE18 was essential for the response, since overexpression of STE4 was unable to activate a response in a ste18 null strain. GPA1 hyperexpression suppressed the phenotype of STE4 overexpression. In addition, cells that overexpressed GPA1 were more resistant to pheromone and recovered more quickly from pheromone than did wild-type cells, which suggests that GPA1 may function in an adaptation response to pheromone.

Stoichiometry of G protein subunits affects the Saccharomyces cerevisiae mating pheromone signal transduction pathway

The Saccharomyces cerevisiae GPA1, STE4, and STE18 genes encode products homologous to mammalian G-protein alpha, beta, and gamma subunits, respectively. All three genes function in the transduction of the signal generated by mating pheromone in haploid cells. To characterize more completely the role of these genes in mating, we have conditionally overexpressed GPA1, STE4, and STE18, using the galactose-inducible GAL1 promoter. Overexpression of STE4 alone, or STE4 together with STE18, generated a response in haploid cells suggestive of pheromone signal transduction: arrest in G1 of the cell cycle, formation of cellular projections, and induction of the pheromone-inducible transcript FUS1 25- to 70-fold. High-level STE18 expression alone had none of these effects, nor did overexpression of STE4 in a MATa/alpha diploid. However, STE18 was essential for the response, since overexpression of STE4 was unable to activate a response in a ste18 null strain. GPA1 hyperexpression suppressed the phenotype of STE4 overexpression. In addition, cells that overexpressed GPA1 were more resistant to pheromone and recovered more quickly from pheromone than did wild-type cells, which suggests that GPA1 may function in an adaptation response to pheromone.

Mechanism of activation of cholera toxin by ADP-ribosylation factor (ARF): both low- and high-affinity interactions of ARF with guanine nucleotides promote toxin activation

Activation of adenylyl cyclase by cholera toxin A subunit (CT-A) results from the ADP-ribosylation of the stimulatory guanine nucleotide binding protein (GS alpha). This process requires GTP and an endogenous guanine nucleotide binding protein known as ADP-ribosylation factor (ARF). One membrane (mARF) and two soluble forms (sARF I and sARF II) of ARF have been purified from bovine brain. Because the conditions reported to enhance the binding of guanine nucleotides by ARF differ from those observed to promote optimal activity, we sought to characterize the determinants influencing the functional interaction of guanine nucleotides with ARF. High-affinity GTP binding by sARF II (apparent KD of approximately 70 nM) required Mg2+, DMPC, and sodium cholate. sARF II, in DMPC/cholate, also enhanced CT-A ADP-ribosyltransferase activity (apparent EC50 for GTP of approximately 50 nM), although there was a delay before achievement of a maximal rate of sARF II stimulated toxin activity. The delay was abolished by incubation of sARF II with GTP at 30 degrees C before initiation of the assay. In contrast, a maximal rate of activation of toxin by sARF II, in 0.003% SDS, occurred without delay (apparent EC50 for GTP of approximately 5 microM). High-affinity GTP binding by sARF II was not detectable in SDS. Enhancement of CT-A ADP-ribosyltransferase activity by sARF II, therefore, can occur under conditions in which sARF II exhibits either a relatively low affinity or a relatively high affinity for GTP. The interaction of GTP with ARF under these conditions may reflect ways in which intracellular membrane and cytosolic environments modulate GTP-mediated activation of ARF.

ADP-ribosylation of cerebrocortical synaptosomal proteins by cholera, pertussis and botulinum toxins

Certain microbial toxins ADP-ribosylate G proteins that may be related to those postulated to participate in secretion, whilst botulinum neurotoxins, produced by Clostridium botulinum, block Ca2(+)-dependent neurotransmitter release. Thus, botulinum, pertussis and cholera toxins were examined for ADP-ribosyl transferase activity using isolated nerve terminals. Although type D botulinum, cholera and pertussis toxins exhibited such enzymic activity, this was not detectable with types A or B botulinum neurotoxins or their individual chains, in any synaptosomal fraction. Botulinum type D and pertussis toxins ADP-ribosylated proteins with mol. wt approximately 24,000 and 42,000 respectively, whereas cholera toxin modified several proteins including a 51,000/47,000 mol. wt doublet. Pre-incubation of synaptosomes with type A, B or D toxins did not inhibit type D-induced labelling in the corresponding lysate. Similar pre-incubations with cholera or pertussis toxins reduced ADP-ribosylation of their substrates. Hence, under conditions in which these botulinum toxins were shown to block Ca2(+)-dependent transmitter release no ADP-ribosylated substrate was produced in the intact nerve terminals. Moreover, direct correlation was not found between the concentration dependencies of type D toxin for protein modification and inhibition of [3H]noradrenaline release from synaptosomes. These collective findings implicate C3, a non-neurotoxic contaminant of type D, in the enzymic action. The substrate for type D toxin was found in the cytosolic fraction and to a lesser extent in synaptic membranes, the reverse of the situation for pertussis toxin. A combination of the membranes and cytosol was required for maximal labelling of the 51,000/47,000 doublet by cholera toxin. Purified synaptic vesicles contained proteins labelled by type D and pertussis toxins but lacked major cholera toxin substrates. Future research will determine the possible involvement of these toxin-susceptible vesicular proteins in transmitter release.

Influence of bacterial toxins and forskolin upon vasopressin-induced inositol phosphate accumulation in WRK 1 cells

The accumulation of inositol phosphates in WRK 1 cells, stimulated with a range of vasopressin concentrations, was diminished by prior exposure to cholera toxin or forskolin, whilst that observed in the presence of maximal concentrations of the hormone was enhanced in pertussis-toxin-treated cells. In the presence of [32P]NAD+, both cholera toxin and pertussis toxin provoked the labelling of peptides with approximate Mrs of 45,000 and 41,000 respectively in the membranes of WRK 1 cells. Exposure to cholera toxin or forskolin for 15-18 h enhanced cyclic AMP accumulation in these cells. The concentrations of these agents which provoked half-maximal cyclic AMP accumulation were similar to those required to diminish receptor-mediated inositol phosphate accumulation by 50%. In contrast, half-maximal ADP-ribosylation of the 45,000Mr peptide needed 100-fold greater concentrations of the toxin than were effective in provoking half-maximal inhibition of inositol phosphate accumulation. Cholera toxin or forskolin also reduced the maximal specific binding, to intact WRK 1 cells, of both [3H][Arg8]vasopressin and the V1a antagonist [3H][beta-mercapto-beta,beta-cyclopentamethylenepropionic acid,O-methyl-Tyr2, Arg8]vasopressin. The kinetics for the loss of this binding capacity following cholera-toxin treatment were very similar to those describing the diminution of vasopressin-stimulated inositol phosphate accumulation in the same cells.

The STE4 and STE18 genes of yeast encode potential beta and gamma subunits of the mating factor receptor-coupled G protein

The STE4 and STE18 genes are required for haploid yeast cell mating. Sequencing of the cloned genes revealed that the STE4 polypeptide shows extensive homology to the beta subunits of mammalian G proteins, while the STE18 polypeptide shows weak similarity to the gamma subunit of transducin. Null mutations in either gene can suppress the haploid-specific cell-cycle arrest caused by mutations in the SCG1 gene (previously shown to encode a protein with similarity to the alpha subunit of G proteins). We propose that the products of the STE4 and STE18 genes comprise the beta and gamma subunits of a G protein complex coupled to the mating pheromone receptors. The genetic data suggest pheromone-receptor binding leads to the dissociation of the alpha subunit from beta gamma (as shown for mammalian G proteins), and the free beta gamma element initiates the pheromone response.

Specificity of action of guanine nucleotide-binding regulatory protein subunits on the cardiac muscarinic K+ channel

The cardiac muscarinic receptor stimulates a potassium-selective ionic current (IK.ACh) through activation of a guanine nucleotide-binding regulatory protein. Purified alpha and beta gamma subunits of the guanine nucleotide-binding regulatory protein have each been reported to open the K+ channel. We have reported that nanomolar concentrations of purified brain beta gamma subunits activated IK.ACh in chicken embryonic atrial patches. In contrast, J. Codina, A. Yatani, D. Grenet, A.M. Brown, and L. Birnbaumer [(1987) Science 236, 442-445] subsequently reported that picomolar concentrations of activated erythrocyte alpha subunits (i.e., the 40-kDa alpha subunit that the authors call alpha K) opened K+ channels in guinea pig atrial patches. In this paper, we further explore the specificity of various beta gamma and alpha subunits in embryonic chicken and neonatal rat atrial patches. Beta gamma subunits from either human placenta (beta 35 gamma) or bovine brain (beta 35,36 gamma) activated IK.ACh whereas transducin beta gamma (beta 36 gamma) did not. The beta gamma activation was consistent in rat and chicken patches [118 of 123 patches (97%)]. Beta gamma subunits opened K+ channels at concentrations greater than or equal to 200 pM and maximally activated the channel at 10 nM. Beta gamma or guanosine 5'-[gamma-thio]triphosphate (GTP[gamma-S]) channel activation could be reversed by alpha 41-GDP. The purified brain beta gamma preparation was contaminated with less than 0.01% unactivated alpha. The detergent (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate; CHAPS), used to suspend the hydrophobic beta gamma, did not activate IK.ACh alone, with buffer, with heat-inactivated beta gamma, or with transducin beta gamma. Unactivated alpha subunits did not open K+ channels. Activated, alpha subunits purified from human erythrocytes (alpha 40-GTP[gamma-S]) or bovine brain (alpha 39-GTP[gamma-S]) at concentrations of 10 pM or higher (up to 1 nM) opened K+ channels less frequently in chicken atrial patches [5 of 27 patches (19%) and 9 of 35 patches (26%), respectively] than in rat atrial patches [5 of 11 patches (45%) and 11 of 19 patches (58%), respectively]. Negative results were not due to patch vesicle formation. Other experiments indicated that alpha and beta gamma activated the same population of channels. Activation of the channel by both beta gamma and alpha subunits implies a more complicated scheme for guanine nucleotide-binding regulatory protein action than previously proposed.

Endogenous inhibitor of the ADP-ribosylation of (a) G-protein(s) as catalyzed by pertussis toxin is present in rat liver

The inhibitor activity of the ADP-ribosylation of (a) G-protein(s) as catalyzed by pertussis toxin was found in the membrane extract of rat liver. The inhibitor activity was found in the fractions of DEAE-Sephacel column chromatography at 50-120 mM NaCl. The inhibitor activity is not due to the degradation of NAD nor to the reverse reaction of pertussis toxin (removal of incorporated ADP-ribose). The present result suggests the presence of an endogenous inhibitor of the ADP-ribosylation reaction of (a) G-protein(s).

ADP-ribosylation by cholera toxin of membranes derived from brain modifies the interaction of adenylate cyclase with guanine nucleotides and NaF

We have developed a method to ADP-ribosylate the stimulatory guanine nucleotide-binding protein of adenylate cyclase (GS) in brain membranes by using cholera toxin. In particular, we used isonicotinic acid hydrazide and 3-acetylpyridine adenine dinucleotide to inhibit the potent NAD-glycohydrolase activity of brain membranes, and we used the detergent Triton X-100 (at 0.1%) to improve the accessibility of the toxin and guanine nucleotides used for supporting the ADP-ribosylation. This method reveals that GS is a very abundant protein in membranes derived from calf brain (approximately 30 pmol/mg of protein). In brain, GS exists in large excess over the previously reported amount of the adenylate cyclase catalytic subunit. The modification of GS with an ADP-ribosyl residue (a) elicits a four- to fivefold activation of adenylate cyclase by GTP, (b) increases the stabilization of adenylate cyclase by GTP, and (c) reduces adenylate cyclase activation by fluoride but does not change basal activity, activation by guanosine 5'-(beta, gamma-imido)triphosphate, or the sensitivity of adenylate cyclase to heat-induced denaturation. A correlation between ADP-ribosylation and the alterations in the activation of adenylate cyclase by guanine nucleotides and by fluoride is presented.

Roles of G protein subunits in transmembrane signalling

A family of proteins called G proteins couples cell surface receptors to a variety of enzymes and ion channels. Since many cells contain several very similar G proteins, an important question is how signals remain specific as they cross the cell membrane.

ADP-ribosylation of membrane proteins by bacterial toxins in the presence of NAD glycohydrolase

The ADP-ribosylation of membrane G proteins is difficult to achieve in tissues that are rich in membrane-bound NAD glycohydrolase (NAD+ glycohydrolase, EC 3.2.2.5). For many animal species this problem can be surmounted by inhibiting NAD hydrolysis with a combination of the anti-tuberculous drug, isonicotinic acid hydrazide, and the NAD analog, 3-acetylpyridine adenine dinucleotide, which act synergistically. In their presence, the ADP-ribosylation of cholera and pertussis toxin substrates reach plateau levels even with only 10 microM NAD. Although 3-acetylpyridine adenine dinucleotide acts as a weak substrate for the toxins, it is simple to estimate its contribution to the ADP-ribosylation and thus to determine the total amount of ADP-ribosylation substrate present in a tissue sample. NAD glycohydrolases that are insensitive to isonicotinic acid hydrazide are also less sensitive to 3-acetylpyridine adenine dinucleotide, but may be inactivated by dithiothreitol. Isonicotinic acid hydrazide adenine dinucleotide, the product of an exchange reaction catalysed by NAD glycohydrolase, runs with NAD in most thin-layer chromatographic systems. It can be separated from NAD, and quantitated, if the chromatographic solvent contains benzaldehyde. Isonicotinic acid hydrazide itself inhibits NAD glycohydrolase. It need not first be converted into isonicotinic acid hydrazide adenine dinucleotide.

Chemically induced hypothyroidism produces elevated amounts of the alpha subunit of the inhibitory guanine nucleotide binding protein (Gi) and the beta subunit common to all G-proteins

Adipocytes of hypothyroid rats display an increased responsiveness to agents which function by inhibiting the production of cyclic AMP. Anti-peptide antisera which selectively recognise the alpha subunit of the inhibitory guanine nucleotide binding protein (Gi) detected a 40 kDa polypeptide in adipocyte plasma membranes of both euthyroid and hypothyroid rats. Amounts of the alpha subunit of Gi were elevated some 2-fold in the hypothyroid preparations in comparison with the euthyroid controls, when equal amounts of membrane protein of the two treatments were examined. As cells from the hypothyroid animals contained 2.7 times as much membrane protein as those from the control animals, the amounts of alpha subunit of Gi are elevated some 5.6-fold per cell in adipocytes of the hypothyroid animals compared with the euthyroid controls. Amounts of the 36 kDa beta subunit of G-proteins were also elevated in plasma membranes of adipocytes of hypothyroid animals, in this case by some 50% when compared on a protein basis. These results provide direct evidence for alterations in the amounts of the subunits of Gi caused by the hypothyroid state.